Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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BACKGROUND OF THE INVENTION
This invention relates to a gas cleaning system for metallurgical ~ ~.,
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Pneumatic metallurgical vessels are. commonly employed for
converting plg iron to steel, These vessels generaily mclude an open ..
upper end for receiving a metallic charge and tuyeres or lances for
delivering oxygen or an oxygen containing gas to tl e metallic 'charge
for the oxidation of such impurities as carb,on, pho$phorous and silicon. .
As a.result oi the reactions within the vessel pollutant gases such as
carbon monoxide and particulate material may bs discharged from the
upper end of the vessel. .
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One type of pneumatic stecl conversion apparatus, commonly
called Q-60P, includes an open topped vessel having tuyeres e~tending
through its lower end for injecting o.~ygen beneath the level of molten
metal within the vessel. In addition, a hydrocarbon shielding fluid,
,¦ such as propane, manufactured gas, natural gas or light oil, is injected
in surrounding relation to the oxygen for prolonging the life of the
j tuyeres and the surrounding vessel refractory. As a result of the
reactions within the vessel and the disassociation of the shielding fluid,
Il pollutant gases and particulate material are discharged from the open
~j upper ond of the vessel. Another type of metallurglcal vessel is the
BOF furnace where oxygen is blown from a lance onto the upper surface
¦ of the metal bath causing the discharge of gases such as carbon monoxid~
and a brown iron-containmg smoke.
ij In order to prevent the discharge of such pollutants, Q-BOP
1¦ and BOF vessels are commonly provided~ with a smoke hood coupled to
a gas cleaning system. Smoke hoods of this type are normally disposed
l ~ above the open uppcr end of the vessel and may include a skirt which is
il mPvable into and out of close proximity with the vessel opening.
11 When Q-BOP vessels, for e~;ample, arc tilted a~vay from the
: ~ 2tl 1¦ smokc hood for sampling and tapping, a gas, normally nitrogen, must be
injected through the furnace tuyercs to prevent the backflow of liquid
1~ metal. ~n enclosure is often provided for contalning the fumes ~,vhich
'î ¦ normally discharge from the vessel durillg such periods. In addition,
¦ when the vessel is being charged with liquid hot metal or scrap through
a door in tl~o nclosure, a seconcl.lry gas emi8sion occura ~ icll must
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also be controlled. One apparatus for collecting such fumes includes a
secondary gas collecting hood which opens into the enclosure and is
¦I disposetl above the access door for creating an indraft so that the
secondary fumes do not pass out of the enclosure. Secondary hoods of
1l this type are connected by a selectively operable valve or damper to
¦ the same gas cleaning system as the primary hood. In order for the
secondary hood system to be effective, the flow rate of air inwardly
through the open access door must be relativel~- higll in order to prevent
Il the outflow of gases emanating from the tilted vessel. Other types of
,~ pneumatic metallurgical vessels, such as BOF furnaces, I~aldo, Besse-
mer and Thomas converters, and argon-oxygen vessels also require
¦ emission collectors in v rying degrees during blowing and non-blowillg
I stages of their respective process cycles.
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SUMMA RY OF TI~E INVENTION
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11 It is an object of the invention to provide a new and irrlproved
gas clcaning system for pneumatic converter vessels.
Another object of the invention is to provide a gas cleaning
! system which produces a high air velocity indraft at the access opening
I¦ f the enclosure surrounding a pneumatic metallurgical converter vessel.
1~ 20 1I These and other objects and advantages of the invcntion ~are¦l achleved by a gas cleaning system surrounded by an enclosure wherein a
secondary hootl opening into the enclosure is selectively connectable to
the furnace gas cleaning system and to the exhaust fan Df an idle furnace ¦
gas clcaning systcm.
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BRII~F DI~SCRIPTION OF THE DR~WINGS
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. FIGURE 1 is a side elevational view, partly in section, of a
¦~ metallurgical vessel and enclosure witll which the present invention is
applicable; . -
Il FIGU~E 2 schematically illustrates a gas cleaning system coupled
'I to the enclosure illustrated in FIGUR13 1;
FIGUP~,E 3 schematically illustrates the gas cleaning system
, II according to the present invention; and
IGURES 4 and 5 schematlcally illustrate an alternate embodiment
of the mvention. .
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DET~ILED DESCRIPTION
. OF THE PE~EFERRED EMBODIMENTS
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1 FIGURE 1 shows a metallurgical vessel 10 to which the present
invention is applicable, and which may, for example, be of the bottom
blown or Q~BOP type. The vessel 10 includes a metallic shell 11
l . and a rcfractory lining 12 which has an opening 13 at its upper end,
ll A plurality of tuyeres 14 extends througll the lower end of the vessel 10
1$ I and each tuyere includes an inner tuyere plpe 14a and an outer tuyere
pipe 14b to pcrmit the injection of oxygen and a surrounding sheet of
¦ hydrocarbon shielding fluid as will be discussed more fully below.
Convcrter vessels of the type illustrated are generally supported in a
I conventional manner on a trunnion ring 15 which has a trunnion pin 16
¦1 extending from each of its opposite sides, Trunnion pins 15 are suitably
supported in a well-known manncr on conventional bearing structures
(not shown) and are couplcd to a s~l.ta~lc dFive mechanism (not showrl)
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for tilting thc vcssel to each of a plurality of positions as may be
required durlng a process cycle,
¦¦ The vesscl 10 is sllown in FIGURE 1 to be disposed ~,vitllin a
metallic enclosure 16 having a skirt portion 17 which extends down-
1l wardly below the vessel and an access opening 18 formed iII one side
~¦ towarcl which the vessel 10 is tiltable. A closure door 20 is mounted
~ I adjacent the access opening and is horizontally movable into open and
: . ¦ cIosed positions relative to the. opening as may be required during a
. l conversion cycle. . - -
, A top opening 22 is formed in enclosure 16 for receiving a s~noke
hood 24 which is preferably water cooled In any suitable msnner such .
!¦ as by belng formed of a tubular membrane construction. Suitable water .
inlet and outlet headers (not shown) are connected to the tubes wllich
form the- hood 25. A second opening 25 is formed ;in enclosure 16 at
1 a point above access opening 18 for receiving the lower end of a
secondary smoke hood 26. A movable skirt 28 is disposed in a tele-
. scoping relation around the lower end of primary hood 24 and is
movable by means (not shown) into and out. of close proximity to the
. opening 13 of vessel 10 as the latter is plvoted into and out of its .
20 . . I various positions as will.be discussed in greater detail below.
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A s schemati.cally illustrated in FIGUI~E 2, the primary smokè . .
1I hood 24 is coupled by a conduit 30 to a gas cleaning system 32 which . .
., may, for e~ample, include a quencher 33 and a scrubber 34. The
Ij quencher 33 and the scrubber 34 include variable throat venturies 36
5. Il and 37 respectively, As those skilled in the art will appreciate, the opening in each venturi may.be varied by a suitable control motor 39.
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A. water-cooled conduit 30 connects the inlet of quencher 33 to the hood
1¦ 29; and a second conduit 41 connects the outlet of quencher 33 to the .
i! inlet of gas scrubber 34. In addltion, an induced draft fan 42 is
- 10. Il . connected to thc outlet of gas scrubber 34 and to a flare stack ~4. The
. '! secondary smoke hood 26 is connected through a bell damper 47 to
¦ condult 41 between quencher 33 and gas scrubber 34. Bell damper 47
is provided for connecting and disconnecting secondary smoke hood 26 ...
t ~o gas cleaning system 32 and includes a generally vertical housing 49 .
15. I¦ . having an inlet 50 connected to conduit 46 and an outlet 52 connected to
- ~ il conduit 41. A water trough 54 is disposed in the interior surface of
1I housing 47 b~tween inlet 50 and outlet 52 and is adapted to have water
¦1 circulated continuously theretllrough. An inverted hollow bell member
55 is movable vertically in housing 49 and between a closed position ...
20. ¦ .shown by full lines in FIGURE 2 wherein its lower peripheral edge is : .
!; immersed beneath the water in trough 54 and an open position shown by
~ broken lines wherein member 55 is above inlet 50. It will be appreci-
Il ated that when bell 55 is in its open position shown by broken lines,
¦¦ - secondary hood 26 is connected to the gas cleaning system 32 whereas
25. Il movement of bell 55 to its closed position showrl by full lines will :
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disconnect the secondary hood 26 from the system 32. In adaition, a
. Il first maintenance damper 57 is disposed in conduit 46 between secondary
hood 26 and bell damper 47, a second maintenance damper 58 is dis-
, 1¦ posed in concduit 41 between quencher 33 and the outlet 52 of damper 47
5. and a third damper 59 is disposed at the inlet of fan 42,
As those skilled in the art will appreciate, quencher 33 is of the
water spray type where coarse dust particles are separated from the gas
stream and scrubber 34 is of the high energy water spray type wherein
,1 the fine fraction of dust particles are removed. - ' '' '
10.I FIGURE 3 shows a second vessel 10', enclosure i7', primary
'1 and se.condary smoke hoods 24~ and 26~ and a gas'cleaning system 32
disposed in spaced ~ apa~t parallel relation to the first vessel ' 10 and
' ¦~ gas cleaning system 32. All of the components of the second system .'
' I are identical to those of the first system and accordingly, each bears
15.Il the same reicrence numeral which is distinguished' by a prime ('). The! gas, cleaning system 32 is shown to be connect-~d to the gas cleaning
system 32' by a conduit 60 which interconnects the inlets 50,and 50' of
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the bell dampers 47 and 47'. In addition, a third exhaust fan 62 may
,, be connected by conduits 63 and 64 to the outlets of gas scrubbers 37
20.I¦ and 37~ while the outlet of fan 62 is connected,by conduits 65 and 66 to
the staclcs 44 and 44' respectively. Maintenance dampers 68 and 70 may :.
be connectcd in conduits 63 and 64 respectively so that the fans 62 may
. I be disconnected from one or both of the gas cleaning systems 32 and
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¦l In a normal operating situation, the vessels 10 and 10' would
each be operated on cycles of alternate periods of production and to
l' permit thc performance of routine maintenance. For example, such
II cyclcs may include eight hours of production time followed by four
5. I hours of idle time or sixteen hours of production followed by eight hours
of idle time. Normally, the idle periods for the two vessels 10 and 10'
will be alternated so that at least one vessel will be in operation at all
times.
Assume, for the purposes of illustration that vessel 10 is being
10. Il operatcd and that vessel I0i is idle. The first step in the steel malcing
i - process of the iIlustrated apparatus is the charging of vessel 10 with
scrap. For this purpose, the vessel is initially tilted to its position
shown in FIGUR13 1 wherein its open upper end 13 IS disposed adjacent
ii the opening 18 and the access door 20 of enclosure 17 IS open. Scrap
` ~ 15. I, metal is then charged into the furnace by means of a chute (not sho~vn).
During this period, there are not normally any emIssIons from the
vessel I0, Next, hot metal is charged into the vessel through z hot
metal charging ladle 72 during which time the tuyeres 14 are preferably
,I not immersed in the metal charge as it is being poured into the vessel
20. I I0 to minimize agitation which could result in unnecessary reactIons of- j, the hot metal with the scrap. ~Towever, even with these precautions,
1I there will be cases when emissions from the vessel I0, symbolized by
¦~ arrows 72, are~ unavoidable and accordingly, the gas cleaning systems
32 and 32' will be operated accordingly. During hot metal charging,
25. ~ ref~ e, It I dosi~able to c roate an in~raft at the acces - peni-g Id
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oI enclosure 17. This is accomplished by closing the variable throat
36 in quenchcr 33 to mmimlze the air flow through hood 24, In addition,
the l~ell damper D~7 and the two maintenance dampers 57 and 53 are open.
Il On the idle side, the variable throat in quencher 33 is closed as are the
5. Il two maintenance dampers 57' and 58' while the bell damper 47' is open.In both the operating and idle systems the scrubbers 37 and 37' and the
dampers 59 and 59' are in their full open,high flow positions. In this
i manner, a substantially greater air flow, symbolized by arrows 74, is
il achieved through tlle access opening by the application of the fans 42
10. Il and 42t from the operating and idle systems to the secondary hood 25
~` ll of the furnace being charged. It is important that not only the volume
of alr flow to the ~secondary hood 26 be sufficient, but the velocity of
the air 74 flowing inwardly through opening 18 should be sufficient to
l¦ ~ overcome the inertia of the gas 72 and the particles e~iting vessel 10.
15. ~ 1¦ . The ciosing of maintenance dampers 57' and 58' in the idle system
i! protects ~,vorliers who may be servicing the idle vessel 10'. Some air ,
j also flows around the lower end of s kirt 17, as symbolized by arrows
76, to insure that the gases 72 do not flow downwardly and around the
il lower end of cnclosure 17,
20. ll After the hot metal charging has been completed, the closure
door 20 is closed and the vessel 10 is rotated to a vertical position with
its top opening 13 disposed immediately below the movable skirt 2~ as
seen in FIGURE 2. As the vessel is rotated, the hot metal charge will
flow over the tuyeres 14 and accordingly, inert gases such as nitrogen
25. ¦ or argon must be dcllvered to the tuyerc6 to prevent them from filling ,, .
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with metal. As a result, emissions ~vill emanate from vessel 10
l and these must bc captured by the gas cleaning system. I~uring vessel
turnup, thcrcforc, the quencher 33, the maintenance damper S~, the
1I scrubber 37, and the fan inlet damper 59 of the operating gas cleaning
5. 1system 32 arc all in their open maximum flow positions. As a result,
a substantial portion of vessel emissions are drawn into the primary
hood 24. In order to insure maximum flow through primary hood 24,
I¦ the bell damper 47 of the operating system 3 2 is closed. In the idle
11system 32', the quencher 33' and the maintenance dampers 57' and 58'
10. 1are closed while-the bell damp~r 47', tbe scrubber 37' and the fan inlet
damper 59' are all in open positions. As a result, the maximum
suction produced by fan 42' is applied to the secondary hood 26 of the
operating system. As a result, maximum ventilation of the enclosure
17 is produced.
15. liAfter turnup has been completed, and thc vessel 10 is in a
- vertical position, the adjustable skirt 28 is lowered into close proxlmity
with the vessel opening whereupon thc main oxygen blow can commence.
This consists of delivering oxygen to the inner tuyere pipe 14a and a
hydrocarbon shielding fluid to the outer tuyere pipe 14b. The o~ygen
20, ¦I rcacts with carbon, silicon and phosphorous in the furnace charge
wherein these oxidized impurities are wlthdrawn either in off-gases or
¦¦ in a slag. In addition, fluxlng agents such as lime may be entrained
¦ in the gas stream for the purpose of desulfurization.~ The hydrocarbon
Il shielding nuid which may take the form of propane, natural gas, manu-
25. ~! factured gas or light oil9 prolongs thc life of the tuyeres 14 and the
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surrounding refractory lining. During the main oxygen blowing pcriod,
the quencher 33, the scrul~ber 37 and the fan inlet damper 59 of the
operating syste~n are maintained in their fully open position. ' Substan-
1l tially all of the gases evolved from vessel 10 are captured by the
S, ll primary hood 24 and processed in the primary system 3 2, Normally,
the fan 'L2 produces a negative pressure within the primary hood 24
' ~I so that there is a slight inflow of air through the small gap that exists
~¦ between the vessel 10 and the movable skirt 28. Toward this' endJ the
- venturi 37 of the scrubber 34 is rn~dulated to produce the desired nega-
10. 'l tive pressure within hood 24. However, some gases may escape into
' ll enclosure 17 due to puffing and slopping around the opening 13 of vessel
10. For this reason, the idle system 32' is adjusted such that positive
ventilation ~,vill be produced within enclosure 17L Specifically, the
!1: quencher 331 and the maintenance dampers 57~ and 58~ are enclosed
15. ¦ while the beil damper 47r and the scrubber 371 are open. The fan
, inlet damper 57~ is pl~ced in a flow modulating position and the speed
of'fan 42 n~ay be reduced.
After completion of the o~ygen blow, the movable skirt 28 is
' 11 elevated and the vessel L0 may then be rotated appro~{imately to its
20. ¦¦ position shown in FIGURE 1 where the molten metal is sampled for
¦¦ ~ chemistry and temperahlre through probes inserted through small
!! openings (not shown) in the closure door 20. If the temperature and
¦¦ chemistry specifications are proper, the vessel 10 is rotated in a
I¦ counterclockwise direction as viewed in FIGURE 1 through the vertical
; ~ 25. !! position and toward a tapping position whercin the liquid rnetal may flow
¦ out of the tapping no~zlc 80 and into' a teaming ladle (not shown)
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positioned thcrebelow. During tapping of the vessel 10, alloying
- ~1 additions may be introduced into the ladle through a feed chute (not
i sho~vn), While tlle vessel is being turned down for sampling and again
when it is being turned up and down to~,vard its tapping position, inert
` 5 1I gases must be introduced into the tuyeres 14. In order to capture the
,1 emissions thus produced, the components of the systems 32 and 32'
~¦ are placed in the same positions as during turnup after the hot metal
ll charge as described above. . :
! It will be appreciated that when vessel 10' is in operation and ..
. . 10 '¦ vessel 10 is idle. the components of the systems 32 and 32' are reversed . .
durlng various stages of operation. Durmg periods when both vessels
: Il lo and 10' are in operatlon at the same time, each of the systems. 32
j~ and 32' are in tbelr operating modes so that if either vessel is in itsIl .main oxygen blowing period and~ its .associated bell damper 47 or. 47' is
15 .!~ closed, the cross connection between the systems will not be achieved. 1
. Il The additional fan 62 is provided to insure continued operation in the .
event of failure of either of the fans 42 or 42l and in addition, may be
¦~ employed to supplement the draft in either of the syslems 32 or 32'.
FIGURE 4 illustrates the application of the present invention to .
: ~ 20 a system having a single metallurgical vessel 10 and its associated gas
~` ~ : cleaning system 32. The systemls secondary hood 26 is connected by a
;.~ . -- conduit 30 and maintenance dampers 57 and 58 to the bell damper 57.
.; ~ I The system also includes a dust collecting or gas cleaning system
. - ¦ 80 whose primary function is to remove particulate matter or clean gase
` . ~ 25 I . relati~e to other apparatus in the steel making facillty. This system,
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for cxample, may include a gas cleaner or scrubber 82, a fan 84 and
, a stack 86. The gas scrubber 82 may take any convenient form such
¦l as a cyclone separator, a wet or dry type of precipitator or a bag t~-pe
filter. The system 80 is normally provided to service a hood 88 which
51l may be disposed, for example, over a reladling pit, or may be
associated with another type of metallurgical apparatus. A first conduit
89 connects the scrubber 82 to the junction bet~,veen conduits 30 and 50
through a maintenance damper 90 and a second conduit 92 conne-cts the
l hood 88 through mainlenance conduit 89,
; 10- ~l During charging of hot metal to the vessel 10 of FIGUR~ 4, the
,i variable throat in quencher 33 is closed and the bell damper 47 and
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the maintenance dampers 57, 58 and 90 are open to connect the
secondary hood 26 into both gas cleaning systems 32 and 80. ~t this
time, it is preferable that the maintenance damper 93 be closed. A*er
` 15 ¦1. charging of the hot metal has been con pleted and the access doors t-o
enclosure 17 have been closed, the vessel 10 is turned up while inert
gas is delivcred through the submerged tuyeres. During this tlme, the
bell damper 47 and the maintenance damper 58 are closed to isolate the
~' secondary hoo~i 26 from the gas cleaning system 32 so that rnaximum
20 - ¦ flow can be achieved through primary hood 24. Dampers 57 and 90,
however, remain open 50 that the secondary hood is connected to the
system 80. After the vessel returns to its upright position and the s~iirt
of hood 24 is lowered into position, the main o~ygen blow may commence .
The maintenance dampers 57 and 90, ho1,vever, may be kept open to
produce ventila-ion of the cnclosurc 17. During this time, dall1per ~3
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may also be opened to connect the hoocl 88 to the system 80.
. I FIGURE 5 shows yet an alternate embodiment of tlle present
invention wherein three vessels 10, 10a and 10b are shown to be
~1 enclosed in enclosures 17, 17a and 17b w~lich are respectively associated . .
1! with gas cleaning systems 32, 32a and 32b, The individual systems are
¦ identical with those discussed with respect to FIGUE~E 3 and accordingly
I will not be described in detail. Each of the secondary hoods 26, 26a
¦ and 26b are respectively connected by conduits 30, 30a and 30b to a :
common cbnduit 100. Bell dampers 47, 47a and 47b respectively
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; ~ . I : connect the common conduit 100 to the corresponding gas cleaning
systems 32, 32a and 32b. Also connected to common conduit 100 is a
hood 88 through maintenance damper 93 and the gas cleaning system 80
through maintenance damper 90. The system illustrated in FIGUR13 5
permits~all three of the vessels 10, 10a and 10b to be operated
lS simultaneously, In this event, the system 80 can be coupled to any
combinatloll of the secondary hoods 26, 26a and 26b by operation of the
maintenance dampcrs 57, 67a and 57b so as to provide the necessary
¦l indraft. . This connection would be accomplished, of course, during
: , those portions of the process cycle when an indraft in the secondary
hood is necessary as indicated with respect to the discussion of the
`':! ' '' system of FIGURE 3, . .
-, . . While the inventlon hss been illustrated and described with
.~ . . respect to :vessels of the bottom blown or Q-BOP type, those skilled in
. . . the art will appreciate that it has application to other types of pneumatic
. 25 stcel making or converter vessels as wcll. Also, wllile onl~ a few
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emb~clirnents o~ tlle p_event Invontion are illustrated and described, i~
is not inten(]ed to be limited thercby but only by the scope bf the
appended claims.
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